FR2718194A1 - Perpetual motion device using hydraulic methods - Google Patents

Abstract

The device consists of a mobile support, which is immersed in water and carries two rotation rollers, which are linked to each other by means of a transmission belt. The belt carries a minimum of seven pairs of cylinders, which are fixed symmetrically on the belt and parallel to each other, with reference to a vertical axis of symmetry. The pairs of cylinders are inverted one to the other and each cylinder contains a moving piston. Each of these is identical for weight and volume and is retained within the cylinder. Each piston, in its descending phase, drives a volume of air towards its opposite cylinder of the pair, through a flexible connecting air pipe.

Description

 The present invention relates to a mechanical assembly immersed in water which causes a continuous, perpetual and autonomous rotary movement.

 In known devices of this kind, no apparatus has performed the same function as this.

By comparison, there is a bucket machine, called noria, which is only used to raise the water, operating on the principle of the hydraulic chain.

 However, this device has the drawback of operating only with the help of an external force such as an engine or an animal for example, and of having the sole function of raising water.

 The device according to the invention makes it possible to avoid these drawbacks.

 In this one, in fact, it is possible to obtain a continuous, autonomous and perpetual rotary movement at will, without any external source of energy to generate the movement. In addition, it is possible to recover energy thanks to the movement thus created. Because if seven pairs of cylinders and pistons are enough to generate the movement, all the additional pairs of cylinders and pistons will provide recoverable energy. Example.

- Device with 10 pairs of cylinders and pistons - 7 pairs to generate the movement - 3 pairs to provide additional energy
Either energy recovered: E = 3 x FVA
With FVA = force volume of air contained in a cylinder due to the buoyancy.

 The movement of the device is slow, but can be powerful by playing on the mechanical reduction by a set of pinions external to the device.

 The device, object of the invention, comprises a mechanical assembly immersed in water, which, by a game of balance between weights which cancel each other and a volume of air which unbalances the system causes a continuous movement.

 The design principle is as follows: 3 elements make up the system: - Identical cylinders and pistons coupled 2 by 2 which aim to expel a certain volume of air downwards.

- A support composed of two rotating rollers and a flexible surface receiving cylinders mounted in parallel, which by its shape cancels the weights and becomes mobile by the volume of air which tends to rise to the surface.

- A fixed frame supporting everything.

 The mechanical assembly immersed in water, forming a mobile support composed of two rotation rollers, an upper and a lower, spaced a certain distance apart, depending on the number of cylinders and pistons desired. Then a flexible hose of a certain width, thus forming a surface for fixing the cylinders and pistons, surrounds and connects the two rotation rollers, like a transmission belt.

 Then, it is fixed on either side of the movable support, on the outer surface of the transmission belt, seven or more pairs, as desired, of identical cylinders in weight and volume, coupled in pairs, symmetrically, and reversed , with respect to a predominantly vertical axis of symmetry, connecting the two rollers by their axis of rotation.

 These cylinders which are mounted in parallel, each have an orifice, called air inlet or outlet, on the side of their closed end. From this orifice, leaves a flexible air duct which connects the second cylinder forming the pair.

 The other end of the cylinders is open, and inside each of the cylinders is a movable piston of a certain weight and a perfect seal between piston and cylinder to trap a certain volume of air.

 Continuous, autonomous and perpetual rotary movement at will is only possible if all the following elements are present: - The entire device is completely immersed in water.

- A minimum of 7 pairs of cylinders and pistons are required.

- Each pair of cylinders and pistons are connected by a flexible air duct.

- All cylinders and pistons are mounted in parallel.

- All the elements that make up the device are of identical weight and volume so that they are balanced with respect to the fictitious axis of symmetry. Thus the forces due to gravity cancel each other out by their symmetry.

- The two pistons of the same pair have a weight greater than the buoyancy of the volume of air trapped in the cylinders.

 Balance condition for two coupled cylinders forming a pair.

 FP1 = weight of the piston of a first cylinder of a pair.

FP2 = weight of the piston of the second cylinder of the pair.

FVA = Archimedes thrust of the volume of air trapped in a cylinder.

 Condition to generate the rotary movement.

FP1 + FP2) FVA with FP1 = FP2
The movement is caused by two forces: - Archimedes' thrust, due to the volume of air trapped in each of the cylinders, which rises to the surface of the water, thus exerting a thrust in the cylinder from the bottom to the top.

- The force of gravity, which drives the pistons down, thus driving the volume of air trapped in the cylinder towards the second cylinder of the pair, for the flexible air duct.

 These two forces are exerted simultaneously. In the first downward phase, it is the force of gravity which acts on the pistons, in the second upward phase, it is the buoyancy which acts on the cylinders.

 As we described above, all the forces due to gravity cancel each other out by their symmetry.

 The volume of air will unbalance the whole, exerting a push from the bottom up, thus creating a rotational movement of the device.

 To summarize the movement, in the first downward phase, the piston, by its gravity, descends into the cylinder, thus expelling a volume of air which passes through a flexible air duct to go inside the second cylinder inverted by the pair, into which the piston located there also descends, thus leaving a free volume to receive the volume of air. The set of identical weight with respect to a fictitious axis of symmetry is unbalanced by the air volume of the second cylinder, by exerting an Archimedes push from the bottom to the top, thus causing a movement.

 The movement obtained is slow but can be powerful by playing on the mechanical reduction and or, the number of cylinders.

 We can see during the movement that there are parasitic frictions contrary to the movement which tend to slow down the rotation. To reduce this friction, it suffices to increase the weight of the pistons, always having a balance of weight, on both sides of the fictitious axis of symmetry. We also note another friction on the axes of rotation of the rotation rollers. To decrease it, this time it will be necessary to decrease the weight of the cylinders, always in symmetry with respect to the imaginary axis, by dressing them with expanded polystyrene for example, or any other material floating on water. The weight of the cylinders can thus approach zero and thus tend to reduce friction. We find that wheel-shaped systems have less friction.

 During this movement, there is a critical phase which stops rotation if the device is only provided with a pair of cylinder and piston. It is reached when the two cylinders and pistons are on the fictitious axis of symmetry.

To remedy this, it is enough to have at least seven pairs of cylinders and pistons to maintain the continuous, perpetual and autonomous rotary movement. In addition, there is an equivalence between the length of the piston, the length of the cylinder, the length of the system, proportional to the stress of the critical phase of a pair of pistons. By seeking the imbalance in the length of the system we fall into an impossibility of conception.

 The perpetual movement is maintained by designing a system in width and not in length.

 In a variant, a system with lightened cylinders does not have this design requirement.

 According to another embodiment of the invention, the device can come in the form of a wheel on a single axis of rotation. In a scale design approach, of a wheel-shaped perpetual energy sensor, the perpetual motion is maintained by at least two pairs of cylinders and pistons.

 To facilitate movement, weights are located in the center of the wheel, divided in half the length of the cylinder to allow the cancellation of its half in the horizontal position of the system. The volume of air must be the farthest from the center to increase the force of Archimedes' thrust. The synchronization of the downward movement of the mobile support can be effected by a mass with its equivalent floating material which would become punctual in a certain position of the wheel, with an adjusted water level.

 The cylinders may be coated with light floating material such as expanded polystyrene in order to reduce the friction forces and the stress of the critical phase to facilitate movement, and may thus be assembled in series. They may also be rigid or in flexible flexible and waterproof membrane, or semi-rigid with accordion-shaped walls forming a bellows.

 The mobile pistons can be floating, respecting the conditions of equilibrium seen above, in order to generate a faster movement. In this case, the cylinders must be reversed. These floating pistons can be located outside or inside the cylinders.

Balance condition:
FP1 = FP2 = Force of Archimedes' thrust exerted by
floating floating pistons.

FVA = Force of Archimedes' thrust exerted by the volume
trapped air.

FP1 + FP2> FVA
The accompanying drawings illustrate, by way of example, an embodiment of the device according to the present invention.

 As shown on the boards 1 to 5, the device comprises a mobile support immersed in water consisting of two rotation rollers (1) connected by a transmission belt (2) on which are fixed symmetrically with respect to a fictitious axis of symmetry (3) and in parallel at least seven pairs of cylinders (4) inside which there is a movable piston (5) which traps a volume of air (6) which, in the descending phase of the cylinder (4), expels this volume of air (6) through an orifice (7) and a flexible air duct (8).

 On plate 1, FIG. 1 shows a cylinder (4) in which there is a movable piston (5) which traps a volume of air (6).

 Figure 2 shows a cylinder (4) in which there is a movable piston (5) which expels a volume of air (6) through an orifice (7) and a flexible air duct (8).

 Figure 3 shows a pair of cylinders (4) and movable pistons (5) connected by the hose (8).

 On plate 2, Figure 4 shows a rigid cylinder (4) with a movable piston (5).

 FIG. 5 shows a variant of the cylinder (4) with accordion-shaped walls forming a bellows.

 Figure 6 shows another variant of the cylinder (4) with a rigid part and another flexible part.

 On Plate 3, Figures 7, 8 and 10 show us the different essential phases of the movement of the system.

 Figure 9 shows the critical phase of the movement.

 Figure 11 shows us a variant of the system, with a mobile wheel-shaped support.

 On Plate 4, Figures 12 and 13 show us that there is an equivalence between the length of the mass (1) the length of the cylinder (L) the length of the system (Ls) and the stress of the critical phase of a pair of piston (P).

 Figure 14 shows us a design in width allowing the maintenance of the movement.

 Figure 15 shows a system with light cylinders, reducing the number of pairs of pistons necessary to maintain movement.

 On Plate 5, Figure 16 shows us a variant of the movable pistons (5). These are floating, and the cylinders (4) are inverted.

 Figure 17 shows us a variant of the cylinders (4).

 These are covered on the outside with expanded polystyrene (9) or any other material floating in the water.

 Figure 18 shows us another variant of movable pistons (5). These are floating and placed outside the inverted cylinders (4).

 On Plate 6, Figure 19 shows us a possibility of using a wheel-shaped perpetual energy sensor coupled to the rotor of an alternator to form an autonomous generator.

 On Plate 7, Figures 20 and 21 show an example of the design of a pair of cylinders and pistons in a wheel-shaped system. The cylinders (1) and the masses (2) form a movable frame (3) relative to two pistons (4) connected together by a rigid tube (5) allowing the passage of air and whose center is here the rotation of the system (6). Weights with their equivalent floating material (7) allow synchronization of the downward movement of the movable frame and upward of the movable support.

 Figure 22 shows an example of the design of a wheel system with four pairs of pistons.

 The device, object of the invention, can be used as a perpetual energy sensor, in all cases where one wants to produce energy. Electricity adapts best to transform this perpetual movement into recoverable energy. We can turn a dynamo, or, depending on the power recovered, an alternator.

 It is also possible to use it as a motor, by multiplying the speed of rotation by a pinion system, up to the desired speed.

Claims (6)

 CLAIMS 1 / Device making it possible to obtain a continuous, perpetual and autonomous rotary movement, characterized in that it comprises a mobile support immersed in water, consisting of two rotation rollers connected by a transmission belt on which are fixed symmetrically and in parallel at least seven pairs of cylinders, with respect to a predominantly vertical or biased axis of symmetry, inverted with respect to each other in the same pair and inside each of which is a piston mobile which traps and expels in the downward phase a volume of air towards the second cylinder of the pair by a flexible air duct, the whole being of the same weight and volume. 2 / Device according to claim 1, characterized in that the weight of the two pistons of the same pair must be greater than the Archimedes thrust exerted on the volume of trapped air and the seal between piston and cylinder must be perfect. 3 / Device according to claim 1, characterized in that the device can be produced according to a wheel-shaped variant on a single axis of rotation predominantly horizontal or bias. 4 / Device according to claim 1, characterized in that the cylinders may be according to another variant, dressed in light floating material such as expanded polystyrene, or be in flexible membrane, flexible and waterproof, or semi-rigid walls in accordion shape forming a bellows, or entirely rigid. 5 / Device according to claim 1, characterized in that the movable pistons may be according to another variant, floating, respecting the conditions of balance of weight, volume and symmetry and by reversing the cylinders. 6 / Arrangement according to claim 5, characterized in that the floating cjiles pistons may be located outside or inside the cylinders.